Inverse inference engine for high performance web search

ABSTRACT

An information retrieval system that deals with the problems of synonymy, polysemy, and retrieval by concept by allowing for a wide margin of uncertainty in the initial choice of keywords in a query. For each input query vector and an information matrix, the disclosed system solves an optimization problem which maximizes the stability of a solution at a given level of misfit. The disclosed system may include a decomposition of the information matrix in terms of orthogonal basis functions. Each basis encodes groups of conceptually related keywords. The bases are arranged in order of decreasing statistical relevance to a query. The disclosed search engine approximates the input query with a weighted sum of the first few bases. Other commercial applications than the disclosed search engine can also be built on the disclosed techniques.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority under 35 U.S.C. §119(e) to provisional patent application Ser. No. 60/125,714 filed Mar. 23, 1999.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

The development of this invention was supported at least in part by the United States National Institutes of Health (NIH) in connection with Small Business Innovation Research Grant 5 R44 CA6161-03, and by the the United States Defense Advanced Research Project Agency (DARPA) in connection with Small Business Innovation Research Contract DAAH01-99-C-R162. Accordingly, the United States Government may have certain rights in the present invention.

BACKGROUND OF THE INVENTION

The present invention relates generally to computer-based information retrieval, and more particularly to a system and method for searching databases of electronic text.

The commercial potential for information retrieval systems that can query unstructured text or multimedia collections with high speed and precision is enormous. In order to fulfill their potential, collaborative knowledge based systems like the World Wide Web (WWW) must go several steps beyond digital libraries, in terms of information retrieval technology. In order to do so, unstructured and heterogeneous bodies of information must be transformed into intelligent databases, capable of supporting decision making and timely information exchange. The dynamic and often decentralized nature of a knowledge sharing environment requires constant checking and comparison of the information content of multiple databases. Incoming information may be up-to-date, out-of-date, complementary, contradictory or redundant with respect to existing database entries. Further, in a dynamic document environment, it is often necessary to update indices and change or eliminate dead links. Moreover, it may be desirable to determine conceptual trends in a document set at a particular time. Additionally, it can be useful to compare the current document set to some earlier document set in variety of ways.

As it is generally known, information retrieval is the process of comparing document content with information need. Currently, most commercially available information retrieval engines are based on two simple but robust metrics: exact matching or the vector space model. In response to an input query, exact-match systems partition the set of documents in the collection into those documents that match the query and those that do not. The logic used in exact-match systems typically involves Boolean operators, and accordingly is very rigid: the presence or absence of a single term in a document is sufficient for retrieval or rejection of that document. In its simplest form, the exact-match model does not incorporate term weights. The exact-match model generally assumes that all documents containing the exact term(s) found in the query are equally useful. Information retrieval researchers have proposed various revisions and extensions to the basic exact-match model. In particular, the “fuzzy-set” retrieval model (Lopresti and Zhou, 1996, No. 21 in Appendix A) introduces term weights so that documents can be ranked in decreasing order relative to the frequency of occurrence of those weighted terms.

The vector space model (Salton, 1983, No. 30 in Appendix A) views documents and queries as vectors in a high-dimensional vector space, where each dimension corresponds to a possible document feature. The vector elements may be binary, as in the exact-match model, but they are usually taken to be term weights which assign “importance” values to the terms within the query or document. The term weights are usually normalized. The similarity between a given query and a document to which it is compared is considered to be the distance between the query and document vectors. The cosine similarity measure is used most frequently for this purpose. It is the normal inner product between vector elements: ${\cos \left( {q,D_{i}} \right)} = {\frac{w_{q} \cdot w_{d_{i}}}{{}w_{q}{}{}w_{d_{i}}{}} = \frac{\sum\limits_{j = 1}^{p}\quad {w_{q_{j}}w_{d_{ij}}}}{\sqrt{\sum\limits_{j = 1}^{p}\quad {w_{q_{j}}^{2}{\sum\limits_{j = 1}^{p}\quad w_{d_{ij}}^{2}}}}}}$

where q is the input query, D_(i) is a column in term-document matrix, w_(qj) is the weight assigned to term j in the query, w_(dj) is the weight assigned to term j in document i. This similarity function gives a value of 0 when the document and query have no terms in common and a value of 1 when their vectors are identical. The vector space model ranks the documents based on their “closeness” to a query. The disadvantages of the vector space model are the assumed independence of the terms and the lack of a theoretical justification for the use of the cosine metric to measure similarity. Notice, in particular, that the cosine measure is 1 only if W_(qj)=W_(dj). This is very unlikely to happen in any search, however, because of the different meanings that the weights w often assume in the contexts of a query and a document index. In fact, the weights in the document vector are an expression of some statistical measure, like the absolute frequency of occurrence of each term within a document, whereas the weights in the query vector reflect the relative importance of the terms in the query, as perceived by the user.

For any given search query, the document that is in fact the best match for the actual information needs of the user may employ synonyms for key concepts, instead of the specific keywords entered by the user. This problem of “synonymy” may result in a low similarity measure between the search query and the best match article using the cosine metric. Further, terms in the search query have meanings in the context of the search query which are not related to their meanings within individual ones of the documents being searched. This problem of “polysemy” may result in relatively high similarity measures for articles that are in fact not relevant to the information needs of the user providing the search query, when the cosine metric is employed.

Some of the most innovative search engines on the World Wide Web exploit data mining techniques to derive implicit information from link and traffic patterns. For instance, Google and CLEVER analyze the “link matrix” (hyperlink structure) of the Web. In these models, the weight of the result rankings depends on the frequency and authority of the links pointing to a page. Other information retrieval models track user's preferences through collaborative filtering, such as technology provided by Firefly Network, Inc., LikeMinds, Inc., Net Perceptions, Inc., and Alexa Internet, or employ a database of prior relevance judgements, such as technology provided by Ask Jeeves, Inc. The Direct Hit search engine offers a solution based on popularity tracking, and looks superficially like collaborative filtering (Werbach, 1999, No. 34 in Appendix A). Whereas collaborative filtering identifies clusters of associations within groups, Direct Hit passively aggregates implicit user relevance judgements around a topic. The InQuery system (Broglio et al, 1994, No. 8 in Appendix A; Rajashekar and Croft, 1995, No. 29 in Appendix A) uses Bayesian networks to describe how text and queries should be modified to identify relevant documents. InQuery focuses on automatic analysis and enhancement of queries, rather than on in-depth analysis of the documents in the database.

While many of the above techniques improve search results based on previous user's preferences, none attempts to interpret word meaning or overcome the fundamental problems of synonymy, polysemy and search by concept. These are addressed by expert systems consisting of electronic thesauri and lexical knowledge bases. The design of a lexical knowledge base in existing systems requires the involvement of a large teams of experts. It entails manual concept classification, choice of categories, and careful organization of categories into hierarchies (Bateman et al, 1990, No. 3 in Appendix A; Bouad et al, 1995, No. 7 in Appendix A; Guarino, 1997, No. 14 in Appendix A; Lenat and Guha, 1990, No. 20 in Appendix A; Mahesh, 1996, No. 23 in Appendix A; Miller, 1990, No. 25 in Appendix A; Mahesh et al, 1999, No. 24 in Appendix A; Vogel, 1997 and 1998, Nos. 31 and 32 in Appendix A). In addition, lexical knowledge bases require careful tuning and customization to different domains. Because they try to fit a preconceived logical structure to a collection of documents, lexical knowledge bases typically fail to deal effectively with heterogeneous collections such as the Web. By contrast, the approach known as Latent Semantic Indexing (LSI) uses a data driven solution to the problem of lexical categorization in order to deduce and extract common themes from the data at hand.

LSI and Multivariate Analysis

Latent Semantic Analysis (LSA) is a promising departure from traditional models. The method attempts to provide intelligent agents with a process of semantic acquisition. Researchers at Bellcore (Deerwester et al, 1990, No. 10 in Appendix A, U.S. Pat. No. 4,839,853; Berry et al, 1995, No. 5 in Appendix A; Dumais, 1991, No. 11 in Appendix A; Dumais et al, 1998, No. 12 in Appendix A) have disclosed a computationally intensive algorithm known as Latent Semantic Indexing (LSI). This is an unsupervised classification technique based on Singular Value Decomposition (SVD). Cognitive scientists have shown that the performance of LSI on multiple-choice vocabulary and domain knowledge tests emulates expert essay evaluations (Foltz et al, 1998, No. 13 in Appendix A; Landauer and Dumais, 1997, No. 16 in Appendix A; Landauer et al., 1997, 1998a and 1998b, Nos. 17, 18 and 19 in Appendix A; Wolfe et al, 1998, No. 36 in Appendix A). LSI tries to overcome the problems of query and document matching by using statistically derived conceptual indices instead of individual terms for retrieval. LSI assumes that there is some underlying or latent structure in term usage. This structure is partially obscured through variability in the individual term attributes which are extracted from a document or used in the query. A truncated singular value decomposition (SVD) is used to estimate the structure in word usage across documents. Following Berry et al (1995), No. 5 in Appendix A, let D be a m×n term-document or information matrix with m>n, where each element d_(ij) is some statistical indicator (binary, term frequency or Inverse Document Frequency (IDF) weights—more complex statistical measures of term distribution could be supported) of the occurrence of term i in a particular document j, and let q be the input query. LSI approximates D as

D′=U _(k)Λ_(k) V _(k) ^(T)

where Λ=diag(λ₁, . . . ,λ_(k)), and {λ_(i),i=1,k} are the first k ordered singular values of D, and the columns of U_(k) and V_(k) are the first k orthonormal eigenvectors associated with DD^(T) and D^(T)D respectively. The weighted left orthogonal matrix provides a transform operator for both documents (columns of D′) and q:

V _(k) ^(T)=(Λ⁻¹ U ^(T))_(k) D′

α=(Λ⁻¹ U ^(T))_(k) q  (1)

The cosine metric is then employed to measure the similarity between the transformed query α and the transformed document vectors (rows of V_(k)) in the reduced k-dimensional space.

Computing SVD indices for large document collections may be problematic. Berry et al (1995), No. 5 in Appendix A, report 18 hours of CPU time on a SUN SPARC 10 workstation for the computation of the first 200 largest singular values of a 90,000 terms by 70,000 document matrix. Whenever terms or documents are added, two alternatives exist: folding-in new documents or recomputing the SVD. The process of folding-in documents exploits the previous decomposition, but does not maintain the orthogonality of the transform space, leading to a progressive deterioration in performance. Dumais (1991), No. 11 in Appendix A, and O'Brien (1994), No. 26 in Appendix A, have proposed SVD updating techniques. These are still computationally intensive, and certainly unsuitable for real-time indexing of databases that change frequently. No fast updating alternative has been proposed for the case when documents are removed.

Bartell et al. (1996), No. 2 in Appendix A, have shown that LSI is an optimal special case of multidimensional scaling. The aim of all indexing schemes which are based on multivariate analysis or unsupervised classification methods is to automate the process of clustering and linking of documents by topic. An expensive precursor was the method of repertory hypergrids, which requires expert rating of knowledge chunks against a number of discriminant traits (Boose, 1985, No. 6 in Appendix A; Waltz and Pollack, 1985, No. 33 in Appendix A; Bernstein et al., 1991, No. 4 in Appendix A; Madigan et al, 1995, No. 22 in Appendix A). Unfortunately, experience with automated techniques has shown that the user cannot readily associate transform axes with semantic meaning. In particular, open statistical issues in LSI are: (i) determining how many eigenvectors one should retain in the truncated expansion for the indices; (ii) determining subspaces in which latent semantic information can be linked with query keywords; (iii) efficiently comparing queries to documents (i.e., finding near neighbors in high-dimension spaces); (iv) incorporating relevance feedback from the user and other constraints.

For these reasons, it would be desirable to have an information retrieval system which addresses the various shortcomings of existing systems, including problems associated with the synonymy, polysemy, and term weighting limitations of those existing systems which employ the cosine metric for query to document comparisons.

BRIEF SUMMARY OF THE INVENTION

In accordance with the present invention, a new system and method for latent semantic based information retrieval, which advantageously employs aspects of the Backus-Gilbert method for inversion, thus eliminating the need for Singular Value Decomposition (SVD). More specifically, the disclosed system recasts measurement of the similarity between a query and a number of document projections as a constrained optimization problem in a linear transform space.

In an illustrative embodiment, the present system performs a number of document processing steps to pre-process the documents in the set of searchable documents, in order to generate a representation of the search space. The system further performs a number of query processing steps to process a search query received from a user to generate a query vector for the query. The disclosed system then performs a measurement of the similarity between the query and document projections as a constrained optimization problem in a linear transform space. The algorithm and mode of solutions are major differences of the disclosed system with respect to the aforementioned vector space and LSI approaches. An additional, major conceptual difference of this approach, with regard to LSI, is that the similarity measurement is not a sequence of two independent steps consisting of: 1) decomposing or transforming the term-document matrix in a lexical transform space defined by the SVD of such matrix and 2) measuring the similarity between each query input the user and each document projection in the fixed transform space determined by the SVD. Instead, the disclosed system, in response to each new query input by the user, determines a new lexical transform space, based on algebraic and computational principles different from SVD, in which to perform the similarity measurement. The decomposition or transformation of the term-document matrix and measurement of similarity are carried out simultaneously in the solution of the constrained optimization problem. This approach brings a dramatic improvement in computational speed. It also provides important conceptual advantages over the unsupervised classification process implied by LSI. These advantages include the ability of the search engine to interact with the user and suggest concepts that may be related to a search, the ability to browse a list of relevant documents that do not contain the exact terms used in the user query, and support for an advanced navigation tool.

The disclosed system provides a computationally superior algorithm for latent semantic retrieval, which is not based on SVD. In algebraic terms, the disclosed approach provides an advantageous compromise between the dimensionality of a semantic transform space and the fit of the query to document content. The efficiency of the disclosed system comes from its building the computation of the distance between the query vector and document clusters in the optimization problem. Alternative embodiments of the disclosed system may employ alternative optimization techniques. In this regard, a number of methods to solve the query optimization problem have been identified in connection with the present invention, including ridge regression, quadratic programming, and wavelet decomposition techniques.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

The invention will be more fully understood by reference to the following detailed description of the invention in conjunction with the drawings, of which:

FIG. 1 is a flow chart showing a series of steps for processing documents and processing user queries;

FIG. 2 shows an architectural view of components in an illustrative embodiment;

FIG. 3 shows steps performed during feature extraction and information matrix (term-document matrix) formation;

FIG. 4 shows an example of an information (or term-document) matrix;

FIG. 5 shows an example of clustering documents represented by the term-document matrix of FIG. 4, and illustrates some of the difficulties of performing document clustering using LSI;

FIG. 6 shows an example of basis function expansion for the single keyword entry “Shakespeare” in an illustrative embodiment of the present invention;

FIG. 7 illustrates a solution of the inverse optimization problem for a number of single term queries;

FIG. 8 shows an illustrative Graphical User Interface (GUI);

FIG. 9 shows an interface to an internet navigation tool;

FIG. 10 is a flow chart which shows a series of steps performed by the internet navigation tool of FIG. 9;

FIG. 11 illustrates an embodiment of a search engine GUI for providing direct and latent information in response to a query;

FIG. 12 illustrates the evolution of concepts or conversations at browsing time; and

FIG. 13 illustrates the concept of hierarchical clustering and categorization with inverse decision trees.

DETAILED DESCRIPTION OF THE INVENTION

The disclosure of provisional patent application Ser. No. 60/125,704 filed Mar. 23, 1999 is hereby incorporated by reference.

As illustrated by the steps shown in FIG. 1, the disclosed system computes a constrained measure of the similarity between a query vector and all documents in a term-document matrix. More specifically, at step 5 of FIG. 1, the disclosed information retrieval system parses a number of electronic information files containing text. In an illustrative embodiment, the parsing of the electronic text at step 5 of FIG. 1 may include recognizing acronyms, recording word positions, and extracting word roots. Moreover, the parsing of step 5 may include processing of tag information associated with HTML and XML files, in the case where any of the electronic information files are in HTML or XML format. The parsing of the electronic information files performed at step 5 may further include generating a number of concept identification numbers (concept IDs) corresponding to respective terms (also referred to as “keywords”) to be associated with the rows of the term-document matrix formed at step 6. The disclosed system may also count the occurrences of individual terms in each of the electronic information files at step 5.

At step 6 of FIG. 1, the disclosed system generates a term-document matrix (also referred to as “information matrix”) based on the contents of the electronic document files parsed at step 5. In one embodiment, the value of each cell in the term-document matrix generated at step 6 indicates the number of occurrences of the respective term indicated by the row of the cell, within the respective one of the electronic information files indicated by the column of the cell. Alternatively, the values of the cells in the term-document matrix may reflect the presence or absence of the respective term in the respective electronic information file.

At step 7 of FIG. 1, the disclosed system generates an auxiliary data structure associated with the previously generated concept identification numbers. The elements of the auxiliary data structure generated during step 7 are used to store the relative positions of each term of the term-document matrix within the electronic information files in which the term occurs. Additionally, the auxiliary data structure may be used to store the relative positions of tag information from the electronic information files, such as date information, that may be contained in the headers of any HTML and XML files.

Weighting of the term-document matrix formed at step 6 may be performed as illustrated at step 8 of FIG. 1. Weighting of the elements of the term-document matrix performed at step 8 may reflect absolute term frequency count, or any of several other measures of term distributions that combine local weighting of a matrix element with a global entropy weight for a term across the document collection, such as inverse document frequency.

At step 9 of FIG. 1, the disclosed system generates, in response to the term-document matrix generated at step 6, a term-spread matrix. The term-spread matrix generated at step 9 is a weighted autocorrelation of the term-document matrix generated at step 6, indicating the amount of variation in term usage, for each term, across the set of electronic information files. The term-spread matrix generated at step 9 is also indicative of the extent to which the terms in the electronic information files are correlated.

At step 16, the disclosed system receives a user query from a user, consisting of a list of keywords or phrases. The disclosed system parses the electronic text included in the received user query at step 16. The parsing of the electronic text performed at step 16 may include, for example, recognizing acronyms, extracting word roots, and looking up those previously generated concept ID numbers corresponding to individual terms in the query. In step 17, in response to the user query received in step 16, the disclosed system generates a user query vector having as many elements as the number of rows in the term-spread matrix generated at step 9.

Following creation of the query vector at step 17, at step 18 the disclosed system generates, in response to the user query vector, an error-covariance matrix. The error-covariance matrix generated at step 18 reflects an expected degree of uncertainty in the initial choice of terms by the user, and contained within the user query.

At step 10, in the event that the user query includes at least one phrase, the disclosed system augments the term-document matrix with an additional row for each phrase included in the user query. For purposes herein, a “phrase” is considered to be a contiguous sequence of terms. Specifically, at step 10, for each phrase in the user query, the disclosed system adds a new row to the term-document matrix, where each cell in the new row contains the frequency of occurrence of the phrase within the respective electronic information file, as determined by the frequencies of occurrence of individual terms composing the phrase and the proximity of such concepts, as determined by their relative positions in the electronic information files, as indicated by the elements of the auxiliary data structure. In this way the auxiliary data structure permits reforming of the term-document matrix to include rows corresponding to phrases in the user query for the purposes of processing that query. Rows added to the term-document matrix for handling of phrases in a user query are removed after the user query has been processed.

Following step 10, at step 11, the disclosed system formulates, in response to the term spread matrix, error covariance matrix, and user query vector, a constrained optimization problem. The choice of a lambda value for the constrained optimization problem set up in step 11 is a Lagrange multiplier, and its specific value determines a trade-off between the degree of fit and the stability of all possible solutions to the constrained optimization problem.

At step 12 of FIG. 1, the disclosed system computes the similarity between each of the electronic information files and the user query by solving the constrained optimization problem formulated in step 11. Specifically, in an illustrative embodiment, the disclosed system generates a solution vector consisting of a plurality of solution weights (“document weights”). The document weights in the solution vector each correspond to a respective one of the electronic information files, and reflect the degree of correlation of the user query to the respective electronic information file. At step 13, the disclosed system sorts the document weights based on a predetermined ordering, such as in decreasing order of similarity to the user query.

At step 14, the disclosed system automatically builds a lexical knowledge base responsive to the solution of the constrained optimization problem computed at step 12. Specifically, at step 14, the original term-document matrix created at step 6 and potentially weighted at step 8, rather than the term spread matrix computed at step 9, is cross-multiplied with the unsorted document weights generated at step 12 (note that the document weights must be unsorted in this step to match the original order of columns in the term-document matrix) to form a plurality of term weights, one for each term. These term weights reflect the degree of correlation of the terms in the lexical knowledge base to the terms in the user query.

At step 15, the disclosed system returns a list of documents corresponding to the sorted document weights generated at step 13, and the lexical knowledge base generated at step 14, to the user.

Overall System Architecture of an Illustrative Embodiment

FIG. 2 shows the overall architecture of the distributed information retrieval system. The system consists of four modules: Indexing 20, Storage 22, Search 24, and Query 26. The modules may run in different address spaces on one computer or on different computers that are linked via a network using CORBA (Common Object Request Broker Architecture). Within this distributed object framework, each server is wrapped as a distributed object which can be accessed by remote clients via method invocations. Multiple instances of the feature extraction modules 21 can run in parallel on different machines, and database storage can be spread across multiple platforms.

The disclosed system may be highly modularized, thus allowing a variety of configurations and embodiments. For example, the feature extraction modules 21 in the indexing module 20 may be run on inexpensive parallel systems of machines, like Beowulf clusters of Celeron PCs, and Clusters of Workstations (COW) technology consisting of dual processor SUN Ultra 60 systems. In one embodiment, the entire architecture of FIG. 2 may be deployed across an Intranet, with the “inverse inference” search engine 23 residing on a Sun Ultra 60 server and multiple GUI clients 25 on Unix and Windows platforms. Alternatively, the disclosed system may be deployed entirely on a laptop computer executing the Windows operating system of Microsoft Corporation.

Further as illustrated in FIG. 2, the indexing module 20 performs steps to reduce the original documents 27 and a query received from one of the clients 21 into symbolic form (i.e. a term-document matrix and a query vector, respectively). The steps performed by the indexing module 20 can be run in batch mode (when indexing a large collection of documents for the first time or updating the indices) or on-line (when processing query tokens). The disclosed architecture allows extensibility of the indexing module 20 to media other than electronic text.

The storage module 22 shown in FIG. 2 includes a Relational DataBase Management System (RDBMS) 29, for storing the term-document matrix. A search engine module 23 implements the presently disclosed inverse inference search technique. These functions provide infrastructures to search, cluster data, and establish conceptual links across the entire document database.

Client GUIs (Graphical User Interfaces) 25 permits users to pose queries, browse query results, and inspect documents. In an illustrative embodiment, GUI components may be written in the Java programming language provided by Sun Microsystems, using the standard JDK 1.1 and accompanying Swing Set. Various visual interface modules may be employed in connection with the GUI clients 25, for example executing in connection with the Sun Solaris operating system of Sun Microsystems, or in connection with the Windows NT, Windows 95, or Windows 98 operating systems of Microsoft Corporation.

Indexing

As shown in FIG. 3, a feature extraction module 21 comprises a parser module 31, a stopwording module 33, a stemming module 35, and a module for generating inverted indices 37. The output of the indexing process using the feature extraction module 21 includes a number of inverted files (Hartman et al, 1992, No. 15 in Appendix A), shown as the “term-document” or “information” matrix 39. The parser 31 removes punctuation and records relative word order. In addition, the parser 31 employs a set of rules to detect acronyms before they go through the stopword 33 and stemmer 35 modules. The parser 31 can also recognize specific HTML, SGML and XML tags. The stopword 33 uses a list of non-diagnostic English terms. For purposes of example, the stemmer 35 is based on the Porter algorithm (described in Harman et al, 1992, No. 15 in Appendix A). Those skilled in the art should recognize that alternative embodiments of the disclosed system may employ stemming methods based on successor variety. The feature extraction module provides functions 37 that generate the inverted indices by transposing individual document statistics into a term-document matrix 39.

The indexing performed in the embodiment shown in FIG. 3 also supports indexing of document attributes. Examples of document attributes are HTML, SGML or XML document tags, like date, author, source. Each document attributes is allocated a private row for entry in the term-document matrix. As noted above, weighting of the elements of the term-document matrix 39 may reflect absolute term frequency count, binary count, or any of several other measures of term distributions that combine local weighting of a matrix element with a global entropy weight for a term across the document collection, such as inverse document frequency. In an illustrative embodiment, high precision recall results are obtained with the following weighting scheme for an element d_(ik) of the term-document matrix: $w_{ik} = {{\frac{{tf}_{ik} \cdot {idf}_{k}}{\sqrt{\sum\limits_{k = 1}^{n}\quad {\left( {tf}_{ik} \right)^{2}\left( {idf}_{k} \right)^{2}}}}\quad {where}\quad {idf}_{k}} = {\log \left( \frac{N}{n_{k}} \right)}}$

tf_(ik) is the frequency of term k in a document i, while the inverse document frequency of a term, idf_(k), is the log of the ratio of the total number of documents in the collection to the number of documents containing that term. As shown above, W_(ik) is the weighting applied to the value in cell ik of the term-document matrix. The effect of these weightings is to normalize the statistics of term frequency counts. This step weights the term frequency counts according to: 1) the length of the document in which the term occurs and 2) how common the term is across documents. To illustrate the significance of this weighting step with regard to document length, consider a term equal to the word “Clinton”. An electronic text document that is a 300 page thesis on Cuban-American relationships may, for example, have 35 counts of this term, while a 2 page biographical article on Bill Clinton may have 15 counts. Normalizing keyword counts by the total number of words in a document prevents the 300 pages thesis to be prioritized over the biographical article for the user query “Bill Clinton”. To illustrate the significance of this weighting step with regard to commonness of certain terms, consider the terms “the” and “astronaut”. The former term likely occurs in 1000 documents out of 1000; the latter term may occur in 3 documents out of 1000. The weighting step prevents over-emphasis of terms that have a high probability of occurring everywhere.

Storage

As previously mentioned, the storage module 22 of FIG. 2 includes a Relational DataBase Management System (RDBMS) 29 for storing the information matrix 39 (also referred to as the “term-document” matrix) output by the indexing module 20. In a preferred embodiment, the interface between the RDBMS and the Indexing and Search modules complies with OBDC standards, making the storage module vendor independent. In one embodiment, the Enterprise Edition of Oracle 8.1.5 on Sun Solaris may be employed. However, those skilled in the art will recognize that a database management system is not an essential component of the disclosed invention. For example, in another embodiment a file system may be employed for this purpose, instead of a RDBMS.

The concept synchronizer 28 is used by a parallelized implementation of the indexing module. In such an implementation, at indexing time, multiple processors parse and index electronic text files in parallel. The concept synchronizer 28 maintains a look up table of concept identification numbers, so that when one processor encounters a keyword which has already been assigned a concept identification number by another processor, the same concept identification number is used, instead of creating a new one. In this way, the concept synchronizer 28 prevents having more than one row for the same term in the term-document matrix.

Search

The search engine 23 is based on a data driven inductive learning model, of which LSI is an example (Berry et al, 1995, No. 5 in Appendix A; Landauer and Dumais, 1997. No. 16 in Appendix A). Within this class of models, the disclosed system provides distinct advantages with regard to: 1) mathematical procedure; 2) precision of the search; 3) speed of computations and 4) scalability to large information matrices. The disclosed system attempts to overcome the problems of existing systems related to synonymy and polysemy using a data driven approach. In other words, instead of using a lexical knowledge base built manually by experts, the disclosed system builds one automatically from the observed statistical distribution of terms and word co-occurrences in the document database.

FIG. 4 shows an example of a term-document matrix 40, and also illustrates some of the difficulties associated with existing systems. The term-document matrix 40 of FIG. 4 is shown, for purposes of illustration, loaded with word counts for 16 keyword terms (rows 42) in 15 documents (columns 44). The example of FIG. 4 illustrates testing of latent semantic retrieval. Topics present in document collection of FIG. 4 are “GEOGRAPHY” (documents b3, b4, b6 and b12), “THEATER” (b1, b5, b8, b9, b10, and b15), and “SHAKESPEARE” (b7 and b11). The keyword “Shakespeare” appears only in documents b7 and b11. The documents semantically related to the “THEATER” topic, however, may also be relevant to a search query which includes the single keyword “Shakespeare”.

FIG. 5 shows clustering for the document collection reflected by the table of FIG. 4, as obtained using an LSI approach, as in some existing systems. The dots in each of the graphs in FIG. 5 are plane projections of individual documents into “concept space”, as determined by a choice of the first few eigenvectors. Documents which deal with similar topics cluster together in this space. The key to successful semantic retrieval is to select a subspace where documents 54 which contain the keyword “Shakespeare” cluster as a subset of all documents 56 which deal with the topic of “THEATER”. This is the case for the two projections shown by the graphs 50 and 52, but not for graphs 51 and 53. Graphs 51 and 53 in FIG. 5 are examples where the “SHAKESPEARE” documents 54 do not appear as a subcluster of the “THEATER” documents 56. Graphs 50 and 52, on the other hand, are examples where the “SHAKESPEARE” documents 54 appear as a subcluster of the “THEATER” documents 56. It is difficult to predetermine which choice of projection axes x-y that will cause the desired effect of clustering the “SHAKESPEARE” documents as a subcluster of the “THEATER” documents. More specifically, it is difficult to predetermine how many eigenvectors—and which ones—one should use with LSI in order to achieve this result. FIG. 5 illustrates that there is no way of pre-determining the combination of axes which cause the “SHAKESPEARE” documents to appear as a subcluster of the “THEATER” documents.

LSI and Matrix Decomposition

The SVD employed by the LSI technique of equation (1) above provides a special solution to the overdetermined decomposition problem

D=ωA

q=ωα

where D is an m×n term-document matrix, q is a query vector with m elements; the set of basis functions ω is m×k and its columns are a dictionary of basis functions {ω_(j), j=1,2, . . . ,k<n}; A and α are a k×n matrix and k-length vector of transform coefficients, respectively. The columns of A are document transforms, whereas α is the query transform. Ranking a document against a query is a matter of comparing α and the corresponding column of A in a reduced transform space spanned by ω. The decomposition of an overdetermined system is not unique. Nonuniqueness provides the possibility of adaptation, i.e. of choosing among the many representations, or transform spaces, one of which is more suited for the purposes of the disclosed system.

LSI transforms the matrix D as D′=U_(k)Λ_(k)V_(k) ^(T) where Λ=diag(λ₁, . . . ,λ_(k)) and {λ_(i),i=1,k} are the first k ordered singular values of D, and the columns of U_(k) and V_(k) are the first k orthonormal eigenvectors associated with DD^(T) and D^(T)D respectively. From this we see that ω=(UΛ)_(k) and A=V_(k) ^(T {A) _(j), j=1,2, . . . ,n}. The columns of A are a set of norm preserving, orthonormal basis functions. If we use the cosine metric to measure the distance between the transformed documents and query, we can show that as k→n ${\cos \left( {A_{j},\alpha} \right)} = {\frac{A_{j}^{T} \cdot \alpha}{{}A_{j}^{T}{}{}\alpha {}} \approx \frac{w}{{}w{}}}$

where w=A^(T)α is the smallest l₂ norm solution to the linear system Dw=q. Reducing the number of eigenvectors in the approximation to the inverse of D has a regularizing effect on the solution vector w, since it reduces its norm.

The present invention is based on the recognition that the measurement of the distance between the transformed documents and query, as stated above is a special solution to the more general optimization problem

min ∥f(w)∥_(n) subject to Dw=q  (2)

where ∥f(w)∥_(n) is a functional which quantifies some property of the solution vector w, n is the order of the desired norm, D is the term-document matrix and q is a query vector. The spectral expansion techniques of linear inverse theory (Parker, 1977, No. 27 in Appendix A; Backus, 1970, No. 1 in Appendix A), wavelet decomposition and atomic decomposition by basis pursuit (Chen et al, 1996, No. 9 in Appendix A) and wavelet packets (Wickerhauser, 1994, No. 35 in Appendix A) provide a number of computationally efficient methods for decomposing an overdetermined system into an optimal superposition of dictionary elements.

The disclosed search engine includes an application of the Backus and Gilbert inversion method to the solution of equation (2) above.

The Inverse Inference Approach of the Disclosed System

Inverse theory departs from the multivariate analysis approach implied by LSI by modeling the information retrieval process as the impulse response of a linear system. This approach provides a powerful mechanism for control and feedback of the information process. With reference to Press et al (1997), No. 28 in Appendix A, the inverse problem is defined by the Fredholm integral equation:

c _(i) =s _(i) +n _(i) =∫r _(i)(x)w(x)dx+n _(i)

where c_(i) is a noisy and imprecise datum, consisting of a signal s_(i) and noise n_(i); r_(i) is a linear response kernel, and w(x) is a model about which information is to be determined. In the disclosed approach to information retrieval, the above integral equation translates as

q _(i) =q″ _(i) +n _(i) =∫D _(i)(x)w(x)dx+n _(i)  (3)

where q_(i), an element in the query datum, is one of an imprecise collection of terms and term weights input by the user, q″_(i) is the best choice of terms and term weights that the user could have input to retrieve the documents that are most relevant to a given search, and n_(i) is the difference between the user's choice and such an ideal set of input terms and term weights. A statistical measure of term distribution across the document collection, D_(i)(x), describes the system response. The subscript i is the term number; x is the document dimension (or document number, when 3 is discretized). The statistical measure of term distribution may be simple binary, frequency, or inverse document frequency indices, or more refined statistical indices. Finally, in the present context, the model is an unknown document distance w(x) that satisfies the query datum in a semantic transform space. Equation (3) above is also referred to as the forward model equation.

The solution to equation (3) in non-unique. The optimization principle illustrated by equation (2) above considers two positive functionals of w, one of which, B[w], quantifies a property of the solution, while the other, A[w], quantifies the degree of fit to the input data. The present system operates to minimize A[w] subject to the constraint that B[w] has some particular value, by the method of Lagrange multipliers:

min A[w]+λB[w]

or

$\begin{matrix} {{\frac{\partial\quad}{\partial w}\left\{ {{A\lbrack w\rbrack} + {\lambda \quad {B\lbrack w\rbrack}}} \right\}} = 0} & (4) \end{matrix}$

where λ is a Lagrange multiplier. The Backus-Gilbert method “differs from other regularization methods in the nature of its functionals A and B.” (Press et al, 1997, No. 28 in Appendix A). These functionals maximize both the stability (B) and the resolving power (A) of the solution. An additional distinguishing feature is that, unlike what happens in conventional methods, the choice of the constant λ which determines the relative weighting of A versus B can easily be made before any actual data is processed.

Implementation of an Illustrative Embodiment the Inverse Inference Engine

The following description of an illustrative embodiment of the disclosed system is made with reference to the concise treatment of Backus and Gilbert inversion found in Press et al. (1997), No. 28 in Appendix A. The measurement of a document-query distance w_(c) is performed by an illustrative embodiment in a semantic transform space. This semantic transform space is defined by a set of inverse response kernels T_(i) (x), such that $\begin{matrix} {{w_{c}(x)} = {\sum\limits_{i}{{T_{i}(x)}q_{i}}}} & (5) \end{matrix}$

Here the document-query distances w_(c) appear as a linear combination of transformed documents T_(i)(x) and the terms in input query q_(i), where i is the term number. The inverse response kernels reverse the relationship established by the linear response kernels D_(i)(x) in the forward model equation (3). In this particular embodiment, the D_(i)(x)'s are binary, frequency, or inverse document frequency distributions. The integral of each term distribution D_(i)(x) is defined in the illustrative embodiment as

H _(i) =∫D _(i)(x)dx

In finding a solution to equation (3), the disclosed system considers two functionals as in equation (4) above. As before, the functional B[w]=Var[w_(c)] quantifies the stability of the solution. The functional A[w], on the other hand, measures the fit of the solution. The degree of fit is measured as the expected deviation of a computed solution w_(c) from the true w. The true w gives the ideal choice of query keywords q″, when substituted into the forward model equation (3). The relationship between a point estimate of w_(c) and w can be written as

w _(c)(x)=∫{circumflex over (δ)}(x,x′)w(x′)dx′

where δ is a resolution kernel, whose width or spread is minimized by the disclosed system in order to maximize the resolving power of the solution. If we substitute equation (5) into equation (3) we arrive at an explicit expression for the resolution kernel δ ${\hat{\delta}\left( {x,x^{\prime}} \right)} = {\sum\limits_{i}{{T_{i}(x)}{D_{i}\left( x^{\prime} \right)}}}$

The Backus and Gilbert method chooses to minimize the second moment of the width or spread of δ at each value of x, while requiring it to have unit area.

These mathematical preambles lead to the following expressions for the functionals A and B:

A=∫(x′−x)²{circumflex over (δ)}(x,x′)² dx′=T(x)·Γ(x)·T(x)

B=var[w _(c) ]=T(x)·S·T(x)

where Γ_(ij)=∫(x′−x)² D _(i)(x′)D _(j)(x′)dx′ is the spread matrix, and

S_(ij) is the covariance matrix of the errors n_(i) in the input query vector, computed as S_(ij)=Covar[n_(i),n_(j)]=δ_(ij)n_(i) ², if we assume that the errors n_(i) on the elements of the input query are independent. By allowing for errors in the input query vector, which is based on the terms in the original query, the present system attaches a margin of uncertainty to the initial choice of terms input by the user. Since the user's initial term selection may not be optimal, the present system advantageously allows for a margin of error or a certain degree of flexibility in this regard.

The optimization problem can therefore be rewritten as ${{\min\limits_{w}{A\lbrack w\rbrack}} + {\lambda \quad {B\lbrack w\rbrack}}} = {{T(x)} \cdot \left\lbrack {{\Gamma (x)} + {\lambda \quad S}} \right\rbrack \cdot {T(x)}}$

subject to T(x)·H=1

where λ is a Lagrange multiplier. The constraint follows from the requirement that the resolution kernel δ has unit area. Solving for T(x) we have an explicit expression for the document transform performed by the present system: $\begin{matrix} {{T(x)} = \frac{\left\lbrack {{\Gamma (x)} + {\lambda \quad S}} \right\rbrack^{- 1} \cdot H}{H \cdot \left\lbrack {{\Gamma (x)} + {\lambda \quad S}} \right\rbrack^{- 1} \cdot H}} & (6) \end{matrix}$

Substituting into (5), we have an expression for the distance between documents and the query q, as performed by the disclosed system: $\begin{matrix} {{w_{c}(x)} = \frac{q \cdot \left\lbrack {{\Gamma (x)} + {\lambda \quad S}} \right\rbrack^{- 1} \cdot H}{H \cdot \left\lbrack {{\Gamma (x)} + {\lambda \quad S}} \right\rbrack^{- 1} \cdot H}} & (7) \end{matrix}$

Note that there is no need to compute the inverse of the matrix [Γ(x)+λS]⁻¹ explicitly. Instead, the present system solves for some intermediate vector y in the linear system [Γ(x)+λS]·y=H, and substitutes y for [Γ(x)+λS]⁻¹·H in (7). A property of the matrix Γ which plays to the advantage of the disclosed system is that it is sparse. The particular computational method used in the vector solution of equation (7) by an illustrative embodiment is LSQR, which is an iterative method for sparse least squares, from a C implementation of the LINPACK library.

Optional parameters available in an illustrative embodiment are: 1) the dimensionality of the semantic transform space; 2) latent term feedback; 3) latent document list; 4) document feedback. The value of the Lagrangian multiplier λ in (7) determines the dimensionality of the transform space. The larger the value of λ, the smaller the number of concepts in transform space, and the coarser the clustering of documents. The effect of the regularization is that relevance weights are assigned more uniformly across a document collection. A relevance judgement is forced even for those documents which do not explicitly contain the keywords in the user query. These documents may contain relevant keyword structures in transform space. By contrast, an exact solution to equation (2) with λ=0 corresponds to the rigid logic of the vector space model, where the documents are untransformed.

In an illustrative embodiment, the disclosed system achieves latency by sorting the coefficients in the solution to equation (7). Positive coefficients are associated with semantic bases which contain the keywords in the query; negative coefficients are associated with semantic bases which contain latent keywords. To understand keyword structures in this transform space, in FIG. 6 we consider the inverse solution for the input query “Shakespeare” for the example term-document matrix of FIG. 4. The graph 62 of FIG. 6 illustrates the comparison of the desired output query q (solid line 63) and the computed output query q′ (undistinguishable from q) for the l₂-norm minimizing solution. The output q′ is computed as a linear superposition of the first seven bases (also shown in FIG. 6), ordered by decreasing coefficients |α_(i)|. Bases with positive α_(i) (basis 1 and basis 2) are shown with continuous lines. Bases with negative α_(i) (basis 3, basis 4, basis 5, basis 6, and basis 8) are shown with dotted lines. The positive bases contain primarily the input query keyword and contribute significantly to the query approximation. They also contain several other keywords (e.g. “theatre”, “comedy”) which are directly associated with the keyword “Shakespeare” across the document collection. These associated keywords must be subtracted in order for the approximation q′ to match the desired output q. The negative bases accomplish this. The negative bases define partitions (or groups) of documents that contain many of the same keyword patterns found in the positive bases, this time never in direct association with the keyword “Shakespeare”. Consequently, the negative bases span the space of the latent semantic documents. Latent semantic documents are documents that, while not containing any of the keywords in the user query, may contain a statistically significant number of keywords conceptually related to the keywords in the user query.

The graph 62 displaying q and q′ in FIG. 6 illustrates that they are virtually identical, and that they accordingly appear as a single plot 63 in the graph 62. In this way, FIG. 6 shows that by forming a linear combination of bases 1 through 7, an approximation of q′ is obtained which is virtually identical to the user query q.

FIG. 7 shows the semantic keyword feedback obtained by isolating positive and negative coefficients in the truncated basis function expansion for the query approximation q_(c). As shown in FIG. 7, the inverse optimization problem is solved for a number of single keyword queries q 72. In addition to a ranked list of documents 74, the disclosed inverse inference engine returns a primary list of conceptually relevant terms q_(c+) 76 (terms directly related to the term in q 72) and a secondary list of potentially relevant terms q_(c−) 78 (terms never associated directly with the term in q 72 but found in documents that describe concepts which are semantically related to the term in q). The illustrative test results of FIG. 7 were compiled based on a random sample of 11,841 documents from the TREC (Text Retrieval Conference, a testing program for search engines sponsored by National Institute of Standards of the United States). In particular, documents in the sample are articles and newswires from the San Jose Mercury News and API.

As illustrated by FIG. 7, the disclosed inverse inference engine actually uses information derived from the data to suggest primary and secondary term lists to the user. Among the top documents returned for each query, several relevant documents may appear which do not contain the input keywords. For instance, the unabridged text of the eighth most relevant document returned from a 0.3 second search of 4,000 articles in the San Jose Mercury News (TREC), in response to the query “plane disaster” is “Upcoming shortly will be a writethru to a0516, PM-Britain-Crash, to update with flight recorders found, experts saying both engines may have failed.”. Note that, while the returned document does not contain any of the keywords in the query (“plane” and “disaster”), it is in fact a very brief newswire about a plane crash which has just occurred. These results are remarkable, considering that this is a very short document compared to the average document size in the collection.

Graphical User Interface and Internet Navigation Tool

In one embodiment of the disclosed system, a GUI is provided in the Java programming language, based on the JDK1.1 and accompanying Swing Set from SunSoft. The GUI consists of a research module for testing various implementation options outlined above, and a more sophisticated module that includes a hypernavigation tool referred to herein as a “soft hyperlink”.

The snapshots in FIGS. 8 and 9 show the illustrative GUI and 80 hypernavigation tool 90. The GUI of FIG. 8 shows the top of the document list retrieved for a TREC-3 Category A (an information retrieval task performed on 742,000 documents from the TREC corpus) adhoc query.

FIG. 9 shows a prototype implementation of the soft hyperlink. The navigation tool of FIG. 9 provides freedom to move through a collection of electronic documents independently of any hyperlink which has been inserted in the HTML page. A user may click on any term in a document page, not just the terms that are hyperlinked. Let's assume that the user clicks on the word “Kremlin”. The disclosed search engine executes in the background and retrieves a list of related terms. A compass display appears with pointers to the first four concepts returned by the engine. Now, the user has a choice to move from the current document to one of four document lists which cover different associations of the keyword “Kremlin”: 1) “Kremlin and Yeltsin”; 2) “Kremlin and Gorbachev”; 3) “Kremlin and Russia”; 4) “Kremlin and Soviet”. An additional modality of the disclosed system allows the user to jump from a current document to the next most similar document, or to a list of documents that are relevant to a phrase or paragraph selection in the current page. The “soft hyperlink” of FIG. 9 provides ease and freedom of navigation without the complexities of a search engine.

FIG. 10 shows steps performed by an illustrative embodiment of the disclosed system for providing an Internet navigation tool. At step 100 of FIG. 10, the disclosed system captures a user indication of an initial term displayed in connection with a document, such as a word being displayed in connection with the presentation of a web page through an Internet Browser application program. The disclosed system may show that the initial term has been captured by causing the initial term to be highlighted with the user display. Alternatively, any other form of indication may be employed, such as underlining, changing color, etc. The initial term may be any one or set of display objects within the web page, and specifically may consist of or include one or more non-hyperlinked display objects. For example, the initial term may include a phrase, a paragraph or a figure indicated by the user.

At step 102, the disclosed system issues an initial search request, via a search engine, using an initial search query consisting of the initial term. At step 104, a plurality of terms that are related to the initial search query are received as search results from the search engine. These related terms may be, for example, sorted in decreasing order of correlation to the initial term. The disclosed system may attach a relevance level to each one of a predetermined number of the initial search result terms, the relevance level reflecting a correlation to the initial term, and these relevance levels may be displayed to the user. In an illustrative embodiment, the relevance levels reflect a lexical correlation between the initial term and each respective one of the initial search result terms.

The disclosed system then selects a predetermined number of the related terms returned by the search engine. The related terms may, for example, reflect the contents of a generated lexical knowledge base. In an illustrative embodiment, the disclosed system presents the selected predetermined number of related terms to the user through a “compass” like display interface, however, this is only one of many ways in which the terms could be presented to the user. For example, in alternative embodiments, such related terms could be presented to the user through a drop-down menus or list, or some other graphical presentation.

The disclosed system then captures an indication from the user of at least one of the related terms. At step 106, in response to the selection by the user of some number of the related terms, the disclosed system issues at least one secondary search request. The search query for the secondary search request combines the selected related term or terms and the initial search term. In an illustrative embodiment, the disclosed system forms a logical AND expression including one or more initial search result terms selected by the user from the initial search result terms, together with the initial search term. The secondary search query thus includes a logical AND expression between selected ones of initial search result terms and the initial term.

The disclosed system then stores a number of secondary search result document weights at step 108, for example in decreasing order. The secondary search result document weights are received in response to the secondary searches issued at step 106, and the decreasing order in which they are stored places the documents that are most related to the secondary search query a the beginning of the list.

At step 109, the disclosed system generates a number of display objects associated with the secondary search results. In this regard, the disclosed system retrieves the electronic information file associated with the first weight in the list of sorted document weights, and displays to the user a portion of that electronic information file containing the first occurrence of the initial search term, with the initial term being highlighted or otherwise emphasized in some way. The disclosed system further retrieves, in response either to a selection or indication by the user, or in response to a predetermined number, one or more electronic information files associated with the document weights generated in response to the secondary searches issued at step 106. The disclosed system displaying portions of these information files containing the first occurrence of initial search term to the user, with the initial search term being highlighted in some manner.

In illustrative embodiments, the user interfaces of FIG. 8 and FIG. 9 may be implemented on Unix, Windows NT, Windows 95, 98 or 2000 platforms and provided with CORBA wrappers for deployment over a distributed network.

Latent Information

In the disclosed inverse solution, a positive and a negative semantic space are considered. Accordingly, the disclosed system returns a list of direct document hits (documents that contain some of the keywords in a query) and a list of latent semantic hits (documents that do not contain any of the keywords in a query, but which may be relevant to a query). The user can switch between the two lists. In an illustrative example, a search on the TREC corpus for a “crisis caused by separatist or ethnic groups” (FIG. 11) would return information on various crises in Transylvania, the Soviet Union and Albania in a first panel 110. When the user selects the latent list, as shown in a second panel 111, a vast body of information on the Lithuanian crisis is discovered, which would otherwise be missed. The articles in the second panel 111 do not contain any of the keywords in the query. Instead, for example, the language in the articles in the second panel 111 refers consistently to a struggle for “independence” and to “a linguistic minority”. The disclosed search technique may locate many more relevant documents than a conventional search engine, because of its latent concept associations. Because the rankings of the positive and latent documents differ by several orders of magnitude, in an illustrative embodiment, the two lists are maintained separately. Alternatively, an empirical weighting scheme may be employed across both lists.

Speed and Memory Usage

An embodiment of the disclosed system provides query times of 7.0 sec for TREC category B (170,000 docs) and 30.5 sec for TREC category A (742,000 docs) on a SUN ULTRA 60, which compares favorably to prior systems. The disclosed system advantageously provides performance times that are sublinear. The scalability of the disclosed approach allows establishment of latent semantic links across extremely large collections, by comparison to what is possible with the SVD approach of existing systems. Memory requirements for the disclosed system vary according to the sparsity of the matrix and term distribution.

Other Commercial Applications of the Disclosed System

A search engine may only be one application of the disclosed information retrieval technology. The disclosed technology may form the basis for a variety of information retrieval tools. Some of these potential applications are outlined below.

Semantic Interpreter

The disclosed information retrieval technology may form the basis for a tool referred to as a “semantic interpreter”. The semantic interpreter summarizes evolutionary trends in news articles, and performs categorization of speech or on-line chat monitoring. It is a browsing tool which allows a user to rapidly compare the content of a current document set to some earlier document set, and/or determine or summarize conceptual trends in a conversation. As illustrated in FIG. 12, the semantic interpreter may perform a search combining a series of terms (query 120) with one or more tag filters 122. The tag filters 122, for example, identify different time intervals corresponding to creation or modification times associated with various ones of the electronic text files or other types of input documents. The tag filters 122 may further indicate specific participants in a conversation, or other identifiable characteristics of specific ones of the input documents represented by the term-document matrix 123. The matrix 123 is subset or partitioned by the subsetting module 124, using tag specification(s) 122, and the inverse inference engine provides concept feedback specific to each of the partitions A 126, B 127, and C 128. This mechanism allows the user to compare the content of a current document set to some earlier document set, and determine conceptual trends. Input to the semantic interpreter could be electronic text from the Web, an electronic database, or digitized speech from a speech recognizer.

Intelligent Sorting of Large and Unstructured Electronic Collections

As shown in FIG. 13, a recursive implementation of the disclosed inverse inference technique leads to a fast method for partitioning database space with groups of bases which are hierarchically arranged in trees. A distinguishing term 132 (for example “CIA”) used to characterize a cluster is dropped from the indices of the term-document matrix 134, after initial differentiation. The inverse inference problem is then solved for the subset of the term-document matrix 134 which clustered around the dropped concept term 132. The new bases are used to partition the parent cluster (CIA). This partitioning is illustrated by the tree graph 130. The tree graph 130 is interpreted top to bottom. The dotted line 131 indicates that the tree is very large, above and below the relatively small section shown in FIG. 13. Above the NASA node 135, and the CIA node 137, there may, for purposes of example, be a parent node (not shown) GOVERNMENT AGENCIES. The CIA node 137 is a child node of such a GOVERNMENT AGENCIES node and a parent node of BUCKLEY 140, FERNANDEZ 141, and the dotted line 131 indicates that there could be one or more children of CIA 137 to the right of FERNANDEZ. An illustrative example of how child nodes may be generated from parent nodes is now described with reference to FIG. 13. Having initially grouped all documents pertaining to the CIA, and considering that each document is a column in the term-document matrix, the constrained optimization problem for the subset of the matrix comprising only these columns may now be solved. The CIA term can be removed, after forming the subset and prior to solving the constrained optimization problem, since CIA now appears in all the documents which form the subset, and it is therefore non-diagnostic. The operation is repeated for all clusters or all major matrix partitions. This recursive scheme should be fast and efficient since the inverse algorithm would be applied to progressively smaller partitions of the term-document matrix. Tests have shown that an inversion for a 100,000×100,000 partition takes an implementation of the disclosed system only about 10 seconds. In addition, this operation is parallelizable with respect to each node in the tree 130. Such “Inverse Decision Trees” could provide a fast and intuitive way to analyze large collections of documents. They could start a revolution equivalent to that caused by the introduction of classification and regression trees in multivariate regression analysis.

Those skilled in the art should readily appreciate that the programs defining the functions of the present invention can be delivered to a computer in many forms; including, but not limited to: (a) information permanently stored on non-writable storage media (e.g. read only memory devices within a computer such as ROM or CD-ROM disks readable by a computer I/O attachment); (b) information alterably stored on writable storage media (e.g. floppy disks and hard drives); or (c) information conveyed to a computer through communication media for example using baseband signaling or broadband signaling techniques, including carrier wave signaling techniques, such as over computer or telephone networks via a modem. In addition, while the invention may be embodied in computer software, the functions necessary to implement the invention may alternatively be embodied in part or in whole using hardware components such as Application Specific Integrated Circuits or other hardware, or some combination of hardware components and software.

While the invention is described through the above exemplary embodiments, it will be understood by those of ordinary skill in the art that modification to and variation of the illustrated embodiments may be made without departing from the inventive concepts herein disclosed. Specifically, while the preferred embodiments are described in connection with various illustrative data structures, one skilled in the art will recognize that the system may be embodied using a variety of specific data structures. Accordingly, the invention should not be viewed as limited except by the scope and spirit of the appended claims.

Appendix A

Below is a list of the documents referred to in the present disclosure:

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What is claimed is:
 1. An information retrieval method comprising the steps of: generating a term-document matrix to represent electronic information files stored in a computer system, each element in said term-document matrix indicating a number of occurrences of a term within a respective one of said electronic information files; generating, responsive to said term-document matrix, a term-spread matrix, wherein said term spread matrix is a weighted autocorrelation of said term-document matrix, said term-spread matrix indicating an amount of variation in term usage in the information files and, also, the extent to which terms are correlated; receiving a user query from a user, said user query consisting of at least one term; in response to said user query, generating a user query vector, wherein said user query vector has as many elements as the rows of the term-spread matrix; generating, responsive to said user query vector, an error-covariance matrix, wherein said error-covariance matrix reflects an expected degree of uncertainty in the initial choice of keywords of said user; formulating, responsive to said term-spread matrix, error-covariance matrix, and user query vector, a constrained optimization problem, wherein the choice of a lambda value equal to a Lagrange multiplier value in said constrained optimization problem determines the extent of a trade-off between a degree of fit and the stability of all solutions to said constrained optimization problem; generating, responsive to said constrained optimization problem, a solution vector including a plurality of document weights, each one of said plurality of document weights corresponding to one of each said information files, wherein each of said document weights reflects a degree of correlation between said user query and the corresponding one of said information files; and providing an information response to said user reflecting said document weights.
 2. The information retrieval method of claim 1, further comprising: parsing electronic text contained within said information files, wherein said parsing includes recognizing acronyms.
 3. The information retrieval method of claim 2, wherein said parsing further includes recording term positions.
 4. The information retrieval method of claim 3, wherein said parsing further includes processing tag information within said information files.
 5. The information retrieval method of claim 4, wherein said tag information includes one or more HTML tags.
 6. The information retrieval method of claim 5, wherein said tag information includes one or more XML tags.
 7. The information retrieval method of claim 6, wherein said parsing further includes extracting word roots.
 8. The information retrieval method of claim 7, wherein said parsing further includes generating concept identification numbers.
 9. The information retrieval method of claim 1, further comprising: generating an auxiliary data structure, said auxiliary data structure being indexed by said concept identification numbers, and said data structure storing the positions of all terms contained within the information files.
 10. The information retrieval method of claim 9, wherein said auxiliary data structure further stores tag information associated with respective ones of said information files, wherein said tag information reflects at least one characteristic of said respective ones of said information files.
 11. The information retrieval method of claim 10, wherein said tag information reflects at least one date associated with each respective one of said information files.
 12. The information retrieval method of claim 2, wherein said parsing includes counting term occurrences in each information file.
 13. The information retrieval method of claim 1, wherein said step of generating said term-document matrix includes generating elements in said matrix reflecting the number of occurrences of each one of said terms in each one of said information files.
 14. The information retrieval method of claim 1, further comprising: determining that said user query includes at least one phrase; and responsive to said determining that said user query includes a phrase, adding a new row to said term-document matrix, each element in said new row containing the number of occurrences of said phrase in the respective one of said information files.
 15. The information retrieval method of claim 14, further comprising determining said number of occurrences of said phrase in each said respective one of said information files by the number of occurrences of the individual terms composing said phrase and the proximity of said terms as indicated by the relative positions of said individual terms contained in said auxiliary data structure.
 16. The information retrieval method of claim 1, wherein said step of generating said term-document matrix includes generating each element in said term-document matrix as a binary weight denoting the presence or absence of a respective one of said terms.
 17. The information retrieval method of claim 1, wherein said step of generating said term-document matrix includes weighting each element in said term-document matrix by a number of occurrence of a respective one of said terms within a respective one of said information files and by distribution of said respective one of said terms across the complete set of said information files.
 18. The information retrieval method of claim 1, further comprising sorting said document weights based on a predetermined ordering.
 19. The information retrieval method of claim 18, wherein said predetermined ordering is decreasing order.
 20. The information retrieval method of claim 1, further comprising automatically building a lexical knowledge base responsive to the solution of said constrained optimization problem, wherein said building includes cross-multiplying said term-document matrix, rather than said term-spread matrix, by said document weights to generate a plurality of term weights, one for each one of said terms.
 21. The information retrieval method of claim 20, further comprising sorting said term weights based on a predetermined ordering.
 22. The information retrieval method of claim 21, wherein said predetermined ordering is decreasing order. 